New Constraints on Gauged U(1)Lμ-Lτ Models via Z-Z' Mixing

Abstract

It is known that the model based on U(1)Lμ-Lτ gauge symmetry can explain not only the discrepancy between the measured value of muon g-2 and the theoretical prediction, but also the structure of the neutrino mass and mixings. We revisit the analysis of the mass matrix structure in the minimal U(1)Lμ-Lτ models based on the latest experimental result, where the minimal stands for the symmetry breaking caused only by a single scalar field. We find that the model called type 2+1, where an SU(2)L doublet scalar +1 with the U(1)Lμ - Lτ charge +1 and the hypercharge +1/2, predicts the B3 texture and is marginally acceptable under the current neutrino oscillation data and cosmological observation. When the U(1)Lμ - Lτ gauge symmetry is broken by the vacuum expectation value of the standard model non-singlet representation such as +1, there are additional contributions to the flavor-changing meson decay process and atomic parity violation via the Z-Z' mixing. We newly evaluate the model-dependent constraints on the model and conclude that the type 2+1 model is robustly ruled out. The model is extended to have an additional vacuum expectation value of a standard model singlet scalar in order to avoid the stringent constraint from the flavor-changing meson decay. Finally, we find the allowed range of the ratio of these vacuum expectation values.